Calculating-machine.



No. 831,633. PATENTED SEPT. 25, 1906- A. SCHNEIDER & J. PERFLER. CALCULATING MACHINE.

APPLICATION FILED APR.30,1903.

14 SHEETSSHEET 1 WITNESSES= ATTORNEYS No. 831,633. PATENTED SEPT. 25, 1906.

. A SCHNEIDER & J. PERFLER.

CALCULATING MACHINE.

APPLICATION FILED APR.30,1903.

14 SHEETS-SHEET 2 TTORNEY N0 831,633. PATENTED SEPT. 25, 1906.

A. SCHNEIDER & J. PBRPLER.

CALCULATING MACHINE.

APPLICATION FILED APB.30,1903.

14 SHEETS-SHEET 3 No. 831,633. v PATENTED SEPT. 25, 1906. A. SCHNEIDER & J; PERPLER. CALCULATING MAGHINE.

APPLICATION FILED APR.30,1903.

14 SHEETS-SEEET 4.

No. 831,633. A PATENTED'SEP-T. 25, 71906. A. SCHNEIDER & J. 'PERFLER.

CALCULATING MACHINE.

APPLICATION FILED APBQQO. 1903.

14 SHEETS-SHEET 5.

Hlli IIIHH .MIIHII No. 831,666. -PATENTED SEPT. 25, 1906.

A SCHNEIDER & J PERFLER CALCULATING MACHINE. APPLICATION FILED APR so 1903 14 SHEETS-SHEET 6.

r Y E N R 0 T T A PATENTED SEPT. 25, 1906. A. SCHNEIDER & J. PBRPLER.

m-samss.

CALCULATING MACHINE.

APPLICATION FILED APR.30,1903.

14 SHEETS-SHEET 'l.

WITNESSES= No. 831,633. PATENTED SEPT.25,1906.

A. SCHNEIDER & J. PERFLER. CALCULATING MACHINE.

APPLIGATION FILED APB.30,1903.

i4 SHEETS-SHEET a.

No. 831,633. PATENTBD SEPT. 25, 1906. A. SCHNEIDER & J. PERFLBB.

CALCULATING MACHINE.

APPLICATION FILED APB..30,1903,

14 SHEETS-SHEET 1Q No. 831,633. PATENTED SEPT. 25, 1906.

' A. SCHNEIDER & J. PERFLER.

' CALCULATING MACHINE.

APPLICATION FILED APR.30,1903.

14 SHEETS-SHEET 11..

' PATENTED SEPT. 25, 130

A'. SCHNEIDER & J. PERFLER. CALCULATING MACHINE.

APPLICATION-FILED APE.30. 1903.

14 SHEETS-SHEET 12 W E r V lTN SSES figs PATENTED SEPT. 25, 1906.

A. SCHNEIDER & J. PBRPLER. CALCULATING MACHINE. AAAAAAAAAAAAAAAAA PR.30,1903.

ssssssssssssssss a.

No. 831,633. 7 PATENTED SEPT. 25, 1906. A. SCHNEIDER & J. PERFLER.

CALCULATING MACHINE.

AiPLICATION FILED APRA BO, 1903.

l4 SHEBTS-SHBET 14.

O nvonroq,

, culating-Machines,

' s r n s a'rnr AUGUST SCHNEIDER AND JOSEPH PERFLER, OF'COLUMBU S, OHIO, AS-

SIGNORS or ONE-HALF TO LEWIS FINK, OF' OOLUMBUS, OHIO.

CALCULATING-MACHINE.

Specification of Letters Patent.

Patented Sept. 25, 1906.

To all whom it may concern.-

Be it known that we, AUGUST SCHNEIDER and JOSEPH PERFLER, citizens of the United States, residing at Columbus, in the county of Franklin and State of Ohio, have invented certain new and useful Improvements in Calof which the following is a specification.

Our invention relates to improvements in calculating-machines; and our object is to produce a machine which shall be compact, easy to operate, and accurate in its operation.

Our improvements are embodied in a machine which employs a series of banks of keys, which keys are adapted to be depressed for the purpose of setting the machine for adding and a printing definite amounts, and our machine is adapted to totalize the amounts and print the total.

We have invented a machine in which the different parts necessary for operating the machine are moved by force applied through the main operating devices, and the keys are used for regulating the movement ofwthe parts operated by the mainop'erating devices.

The main operating devices are controlled by means of a crank, and the construction is such that the setting of parts for totalizing is accomplished in large part by force .to the crank of the machine, and little orce ap lied is required to be ap lied through the keys of ,thernachinawhich avea trigger-like effect,

' the force necessary to set andmove the parts being applied through the crank. In our machine the printing mechanism cooperates with the actuating mechanism, so as to render the operation more'positive and decrease the amount of force necessary to be applied to operate the machine.v

In the drawings, Figure l'is a top plan view of the machine. I Fig. 2 is a transverse sectional-view on the right side of the ma chine, taken on the line m as of-Fig. 1. Fig. 3

is a transverse sectional view at the left side of the machine, taken on the line y y of Fig.

1. Fig. 3 -is a sectional view of the shaft 2 and its supporting mechanism. Figs. 4 and -5 aredetail views of one of the banks of keys and the frame for supporting same. Figs.

6 to 9 inclusive, are detail views of arts connected with the key-bar's of our mac 'ne. Figs. 10, 17, 18, and 24 are sectional views of the main operating mechanism. Figs. 11 to 16, inclusive, are detail views of parts ofv "line-y yof Fig. 1 looking I same. Figs: 19 to 21, inclusive, are detail views of the shaft for the adding-wheels. Figs. 22 and 23 are detail views of parts of the totalizing mechanism. Figs. 25 to 30, inclusive, are detail views ofv the transfer mechanism. Fig. -31 is a detail view of the strip mechanism for preventing a partial operation only of the machine. Figs. 32, 33, and 34 are views of thel'actuating parts for the adding-wheels. Fig. 35 is a transverse sectional view showing the adding-wheel and transfer mechanism in elevation. Fig. 36 is a transverse sectional view of the printing mechanism. Fig. 37 is a detail view of the mechanism for advancing the paper stri Figs. 38 and 39 are side viewspf the H1801}; anism for operating the type-ribbon. Figs. 40 to 47, inclusive, are detail views ot parts of the printing mechanism. Figs. 48 to 51,

inclusive, and 53 are detail views of the opera..

ating-crank of the machine. Fig. 52 is a longitudinal sectional view taken through, the machinebetween the addin wheels on the to t e right thereof, eels in elevation.

showing the adding-w Like parts are represented by similar characters of referencc in the several views.

.Fmme and shafts. The frame of our machine is indicated by the letters A A. The shafts (indicatedby the numerals 1, 2, and 3, FignZ) extendthrough the machine and are supported by the side frames. The keyframe for supporting the push-keys is constructed the same as shown in our prior pat-' ent, No. 682,755, dated September17, 1901, to which reference is here made, and we employ a similar rack-bar and lock-bar as shown and described fully 1 in said prior atent. These bars are for locking. the pusheys in "a-"prsa p'osition and for locking the undepressed keys of one bank in undepressed position after any one key has. been depressed. The push-keys a are supported by a keyboard, which is a art ofthe framework of the machine, and tiiese push-keys are adapted to slide within guides formed in the keyboard, as shown in Figs. 4 and 5.

Keys cmd key-bara-The push-keys a are known as value-keys and consist of a button, Fig. '1, with the proper numeral indicated thereon and a key-stem which extends downwardl having a pin a extending from the stem orrthe ke which cooperates with the lock and rack are to effect the locking of the keys. A stop a on the key-stem determines the extent of movement of the actuating part for the adding-wheel, there being an actuating device for each bank of keys.

a? indicates the rack-bar, and a; the teeth on said rack-bar, having shoulders a A spring a normally holds said rack-bar in proper position to be moved by the push-key.

a indicates the lock-bar, and a the foot of said bar.

We employ key-springs for holding the keys in their normal position, and the parts thus far described operate in the same man ner as those set forth and described in our prior patent, No. 682,755, to which reference has heretofore been made.

Main operating devices.-The main operating-shaft (marked 1) is indicated in Fig. 2, and the crank-handle for our machine is connected to said shaft, as shown in Fig. 1. The main sector I) is part of the main operating device, and the'auxiliary sector 1) constitutes part of the auxiliary actuating mechanism for the printing devices. Said main sector I) is journaled rigidly to'the shaft 1, whereas the auxiliary sector I) is loosely journaled on said shaft and. is adapted to-be operated directly by the main sector I), as hereinafter specified. Each main sector gears with. a main operating-Wheel b Figs. 2

' and: 3, and the operating-wheelis composediof the parts indicated in Fig. 24. The/ main operating-Wheel is also part ofthe main operating device of our machine. The hub b is. journaled' loosely on the shaft 2, and the main wheel b is supportedon the flange of said! hub. and is adapted to be moved by the mainsector'badimited distance thereon with-' out moving the-huh; The wheel-b is held; on said hublfi by aserew-threaded cap k shown in said. figure. A spiing bficontainedwithinthe hub of saidmain operating-wheel; has one end; attached to-the shaft 2, while the other end 0% said spring-isattached to the-hub, andconse uently whenever the hub isrotatedit puts t e spring li -under tension. The shaft 2 is rigidly joumaled; to the-frame of the machine. -A pin b9, Figs. 1'2 and 18, extending from the side otthe hub,- is adapted to con j tact with the shoulder k formed in the slot 12 which: is shown in-thelflange of the main operating-wheel, sorthat when the main op crating-wheel has-been rotated a predetermined distance byits connection with the main. sector 6 said operating-wheel will. upon its further rotation advance the hub with it in the direction ofthe arrow shown in Fig. 1-7.

and Wind up the spring I), which we shall term the motorespring for the machine. Upon the return movement of the parts the motor-spring b will ordinarily return the hub to its normal position; but in order to insure the return of said hub under any and all con.- ditions we'have shown a pivoted catch bi, Fig. 17, hereinafter more specifically referred to, which upon the return movement of the hub will. connect the hub with the main operating-wheel and return the hub positively to its normal position in the event the motorspring b does not act to return the parts. In this way we attain a limited initial movemeiit of the main operating-Wheel before it operates to rotate the hub, which hub is connected with the actuating mechanism for the adding wheels and other parts of the machine. This is especially desirable for the purpose of setting certain mechanism, as

hereinafter explained.

The main operating-wheel rotates indi-. pendently of the hub b until thepin 1) contacts against the shoulder 7c, Figs. 17 and 18; Thereafter the parts move togetheruntil the pivoted catch 6 is depressed by the contact of the pin t against the part 1) near the end of the return movement. The pin t, Fig. 17, upon the hub 11 thereupon moves out of the notch formed in thecatch .55, (shown clearly in Fig. 17,) and the catch thereafter moves free fromthe'pin, so that the main operating-wheel continues its return movement free and independent of the hub b In other Words, the main operating-Wheel first rotates an initial distance independent of the hub and then continues its rotating movement connected with. the hub and near the end of its return movement is disconnected from the hub and continues its return movement independent of the hub. This permits the operating-wheel to have a limited amount of movement at the beginning free and independent of the hub, which is desirable' for the purpose of setting parts of the mechanism, and a limited movement at the.

end of its rotation free and independent from I the hub which is desirable for the purpose-of insuring the release of the actuating-mechanism, as hereinafter explained. The pivoted pawl?) 0nthe hub 12 is heldfin normal position by the pin 7c, Fig. 17, contacting with the tail of said pawl. This pawl is adapted upon the-return: movementiof. the sector to,

engage with; a rod for resetting the transfer mechanism, as will b e: hereinafter described, and at the BHdOf the .neturn'movement of the hub the pin k1 causes thepawl to be raised out of engagementwith said rod, which is ad ted to reset the'tmnsfer mechanism. We ave shown. a rod-4, which extends a rose the-machine, said rod being supports by arms I), extending from thehu -11 of. said operatingiwheel, Fig. 3. .'Dhrough this rod e, as hereinafter explained, the hubl) isadapted; toscause-thereturn ot the actuating parts bOrIIOIIIlfil position after they have operated the-'adding-wh'eelsfand; the pawl b is adapted to cause'the return ofzthe transfer mechanism. We have termed the. hub if and the rod 4- auxiliary operating mechv anisiii, T the wheel 1J being the main operating Wheel, which is directly operated by the sec+ s31,eae

of any ey of a particular bank. Said actuating parts are further held against movement by the contact of the rod l against their tails, and this rod is moved away from contact whenever the rank of the machine is operated. Consequently the actuating parts are released by the depression of a key and by the movement of the crank, and until both operations are performed the actuating parts cannot actuate the adding wheels. This rod 4 is adapted upon-the return movement of the operating wheel and sector, by

contact against the tails of the actuating parts hereinafter specificallydescribed, to restore them to their normalpositions.

On the shaft 2 between the respective main operating-wheels b we have shown for each denomination represented on the keyboard a bushing b, loosely ournaled on said shaft, with bifurcated arms 1) extending upwardly, forming an actuating-arm for the adding-wheel, Figs. 33and 52. An exterior bushing-Z) is journaled loosely on said first-mentioned bushing and has arms orplates 1) extending upwardly, Fig. 33, which are adapted; to support the end of the actuating-bar b ,'wl1ich carries the tooth .7).

(Shown in Figs. 27 and 33.) The loose end 6 Fig. 35, of said actuating-bar b is ada ted to move freely within a slot 1) of the link I). The link 6 is supported on the rods 5 and- 6, which extend from the bars 6 there being onebar on each side of the machine. Said bars are pivoted on the frame of the machine and with the rods 5 and 6 constitute what may be called the supportingaframe for the actuating mechanism. A Figs. 33 and 35, which holds the actuating bar 6 connected with the arms or plate 6, extends through slotted openings 5 Fig. 35, formed in the actuating-arms 5 ted opening permits movement of the actuating-bars independent of the actuating arms, and theslot is of such length as to permit the actuating-bar to have sufficient independent movement to move the addingwheel one tooth for transferring purposes, as will be more fully explained hereinafter.- Arms 6 connected with said main supporting-frame, Fig. 27, extend on each side of the machine in a forward direction (toward the operator) and by reason of the contact of the rear part of said arms. near the pivotal point in b,

This slotof same, against the rod 6, extending-from said supporting-frame, are adapted to raise said supporting-frame for the purpose here- -ment ofthe pawl I) with the periphery of the disks, hereinafter mentioned, so as to avoid inaccuracies in the construction. The purpose of the pawl 11 is to determine the extent of movement of the actuating art I) during the totalizing operation, as wi 1 be explained.

In general the operation of the actuating part registers on its corresponding addingwheel the amount determined by the key depressed in that particular bank of keys and further cooperates with the printing mechanism to cause said amount to be printed on a tape. The tooth b on the actuating-bar hereinbefore mentioned is during this operation held in engagement with its corresponding adding-wheel during the forward movement of the main operating mechanism, and upon the return of said mechanism'the tooth is raised out of engagement with the addingwheel by the raising of the supporting-frame hereinbefore mentioned, thereby leaving all theaddingavheels that have been operated in their advanced position. v For the purpose of totalizing amounts the actuating-arms may be released from engagement with their corresponding addingwheels prior to the movement 'of the actuating-arms by the depression of a key known as the total-key, (shown in Fig. 1 to the left of thevalue-keys) andthe tooth of the actuating-bar during the movement of the actuatingarm when totalizing is done will be raised and held out of engagement with its corresponding addingwheel. The extent of movement of the actuating-arm is determined by the pawl b in the following manner: Each adding-wheel b" is formed with a disk I). The addingwhcels are shownherein with'fifty teeth on the periphery thereof and five teeth on. the disk. lnnormal position when the addingwheels are all at zero and before the opera tion of any actuating-arm the pawl b will contact with one of said five teeth on the periphery of said disk, but after the addingwheels have been advanced by an actuatingarm the teeth. on the periphery of the disk will move away from contact with said pawl I), so that when totalizing is done the actuating-arm for each adding-wheel will be per mitted to move throu h the agency of the actuating-spring herein )efore referred to until said pawl contacts with the tooth. nearest it on the periphery of the disk. Each. actuatingarin F) has a spring I2 which may be termed registering operation, as well as the totalizing operation, the only difference'being that during the registering operation said spring will also operatethe registering-wheel through the engagement of the tooth b with the teeth of the registering-wheel, whereas during the totalizing operation the actuating arm will be advanced without operating the registering-wheel. The supplementary arm I) normally contacts with and is held in normal. position by the rod 4. A spring I) tends to draw the lower end of said supplementary arm 1) forward, Fig. 34, and the upper end of said arm rearward whenever said rod 4. is raised out of contact with the lower end of said supplementary arm. The function of the supplementary arm is to hold or look the actuating-armuntil the crank of the machine-is operated, -the rod 4 being directly arm I).

connected to the hub-b which hub'is oper-' ated by the sector I) through the agency of the crank. Consequently the actuatingarms mayiall be released, but same cannot moveuntil the rod 4 is moved away from contact with the tail of the supplementary A pawl b pivoted on the actuating-arm b, is normally held with its rear end in depressed position by a spring I), Fig. 34,

- and this 'pawl b is adapted to contact against the stop b which is in line with the lug b extending upwardly from said pawl. Consequently the actuating arm is held against operation by the actuating spring on account of the stop '1), normally contacting against the lug b. When, however,. the stop 5 is raised, the actuating-arm will be unlocked, but it still cannot be advanced by the actuating-spring until the rod 4 is raised through the agency of the crank or handle of the machine. The r-actuatin arm after a key is depressedand the cran o erated will then move until the projecting ug b, Fig.

34, contacts'against a stop formed on the stem of the key, which stop is then thrown into the path of movement-of the lug by the de ression of the key. The. actuating-arm w' l be advanced by the actuatingi spring, which spring is rewound bythe motor-spring hereinbefore referred to. This rewinding is' effected by the rod 4, contactin against the tail of the actuating-arm, and when the rod ,4

- is returned to normal position by the main motor-springs the actuatmg-arm will be returned to normal p'ositionand the actuatingspring wound up.

Locking devices.--In addition to the. looking devices for the actuatingFaflnS hereinbefore referred to there are looking devices shown herein which are necessary to insure accuracy during the totalizing operation. Durin the totalizing operation no one of the valueeys can be thrown into depressed.

position. Consequently the actuating-arms will be free to move an unlimited distance,

excepting for the following means: A looking-bar b, Fig. 3, is adapted to be thrown into engaging position with the teeth of the adding-wheels at the beginning of each totalizing operation. The actuating-arms will therefore be advanced by the actuatingspring until the pawl 1) contacts against one of the five teeth on the periphery of the disk connected with the addin -wheel, and through the agency of this bar I), which holds the adding-wheel against movement, the actuating-arms will be held against further movement; but the adding-wheels must be released from said locking-bar at the beginning of the return movement of the actuating-arms, for so soon as the bar b is thrown out of engagement with the addingwheels the actuating-arms would be free to move the adding-wheels an additional distance, and thusdestroy the accuracy of the totalizing operation, excepting for the following mechanism: The supplementary arm I) having been released from contact with the rod 4 will move with the actuating-arm b. The actuating-spring 6 is of stronger tension than the spring bl, Fig. 34, so that the actuating-arm and supplementary; armwill retain the relative position shown in Fig. 34 until the actuating-arm b is released by the pawlxb contacting against one of the teeth on the adding-wheel. The spring I) will then move the supplementary arm b .inde'- pendent of the movement of the actuatingarm into a position forward of the actuatingarm, and the pawl b will thereby be released from tension of the-springb, and the pawl being wei hted at the rear will be raised until the shoulder of said and contacts with one of the pins on sai key-frame. The

lock-bar b will then be withdrawn from engagement with the adding-wheels; but the actuating-arms will be locked by the enga ement of the pawl b. as net explained. I he parts will be held locked until the rod4 upon its return movement depresses the tail of the supplementary arm I) and moves the upper end of 1 said arm to the position shown in Fig. 34, when the spring I)" will be put under tension and depress the rear end of said awl out of position to engage the teeth, an the rod 4 will then move the actuating-arm back to normal position. a

-The shaft 2 is slotted at its end, as shown in Fig. 21, and a ratchet b is formed with a key whichextends into the slot of said shaft, and by means of the connection shown in Figs. 19' and 20 the shaft and actuatingsprings are woundup throu h the ratchet b and held leckedby the paw b. The lookv. 0

loosely on the ,advanced ing-bar Z2 is supported by arms 5 on the rear side of the machine, which arms are journaled shaft 7. An arm 6 Fig. 3, is also journaled loosely on said shaft 7 and is connected by the link I) to the rod 6, extending from the side arm I). The arms I) and b are held connected by a spring 6 so that said locking-bar may be adjusted for any inaccuracies in the construction. It will be seen that whenever the side arms are raised for the purpose of throwing the tooth of any actuating-bar out of engagement the adding-wheels will all be locked by said locking-bar b.

Returning mechanismfor actuating-arms For the purpose of disengaging the teeth I) of the actuating-bar from its corresponding adding-wheeh so that the actuating-arms may be returned to normal position without returning the adding-wheels, but, on the contrary, leaving them in their advanced position, we have shown the auxiliary sector 1) formed with a pivoted pawl 0, Figs. 2, 11, and 1-5. During the rearward movement of the actuating-arm when the adding-wheels are for registering purposes the auxiliary sector I) is held connected with the main sector I) and moves therewith. The pawl c is pivoted on a pin 0", which pin extends through the bifurcated arms of the auxiliary sector. The bifurcation is such that the tail of the pawl is normally held against the auxiliary sector by the tension of a spring a", and the arrangement is such that the pawl in the against the tension of the and 15;) but at the beginning of the return -movement of said auxiliary sector the tail of rearward movement of the auxiliary sector contacts against the pin 0 formed on a crankarm 0, and is free to move past said pin 0 spring 0 Figs. 12

the pawl contacts against the auxiliary sector and thepawl forces the lowerend of the crankarm 0 outwardly until it is caught and held by thespring-pressed catch c The crank- 45,

frame for the actuatin arm 0 is connected with the supporting bar,here1nbeiore described, by the curved bar I), Fig. 2. The

, result of this construction is that the supthrown upwardly in order porting-frame at the beginning of the return movement of the auxiliary sector I) is raised, and thereby the teeth on the actuating-bars are disengaged-from the adding-wheels and the same are held disengaged by the catch a engaging and holding the crank-arm 0*, as

hereinbefore described. The movement oi" the actuatingfarms back to normal position will therefore respective actuating-bars are out of engagement with the adding-Wheels. Consequently the actuating-bars will be returnedto normal position, leaving the adding-wheels in their advanced position. The catch is to release the and permit the supportingback to normal position at the crank-arm a frame to drop be made when the teeth on the end of the return movement of the auxiliary sector b. This is effected by a lug c, Fig. 10, on themain sector I) contacting with the end of said catch 0 and raising it out ofengagement with the pin on said crank-arm c This is effected. at the end of the return movement of the main sector I) and auxiliary sectort.

The auxiliary sector and the main sector are held connected by a double-arm link 0 pivoted to the main sector I) and held in normal position by the spring shown in Fig. 10; but this link is adapted to be raised at certain times, so that the pin 0*, Fig. '14, is disengaged from the groove formed in the auxiliary sector b, Fig. 10. So long as the pin 0 rests within the groove the main sector and auxiliary sector will be held connected; but when the double-arm link c is operated the pin 0" will be raised temporarily from the groove and the main sector may then move without transmitting motion to the-auxiliary sector. During this operation the pin will, during the movement of the main sector 6, travel upon the periphery of the auxiliary sector. This disconnection of the main sector and auxiliary sector is effected when the machine is to be operated for clearing purposes, a time when the actuating-arm shall be returned while operating the adding-wheels, and it is therefore necessary that the actuating-bar be dropped to engage the respective teeth with the adding-wheels at the beginning of the return movement of the actuating-arm. This is effected by the following mechanism: The pin 0 will, at the end of the rearward movement of the sector I) when the auxiliary sector is disconnected therefrom, rise over the head.

of the spring-pressed catch 0", ,pivoted to the auxiliary, sector I), so as to operate said catch at the beginnn'ig olthe return movement of said sector, and the pivoted catch when moved will raise the catch 1: out of engagement with the crank-arm 0 thereby permitting the supporti11g-fran1e I) to drop until the teeth on the actuating-bars engage the corresponding adding-wheels, so that upon the further return movement of the main sector the adding-wheels will be moved with the actuating-arms back to normal position; which will result in restoring all the adding-wheels to zero position. (See Figs. 11 and 15.) It will thus be seen that the pin 0 will normally be locked within the groove of the auxiliary sector I), and thereby hold the auxiliary sector and main sector connected; but when the pin 0 is raised out of the groove it will accomplish the result of throwing the spring-pressed catch a at the beginning of the return moven'ient ol' the main sector, and thereby release the catch 0 from engagement with the crank-arm and effect the engagement of the actuating-arm with the corresponding adding-wheel. This moven'ient of the double arm is effected by the parts contransferring purposes.

ends, the center of both curves being the pivotof the arm, butof different radii, the two ends being connected by an inclined portion df. The pin (1 extending from the plate I), which plate is connected with the actuating-bar, as hereinbefore explained, locks said tooth bf. in engagement with the adding-wheel by means of the peculiar form of the slot. A pin (2", formed on said pivoted arm d, extends within a vertical slot d formed in the actuating arm b and thereby provides for a limited movement of said pivoted arm for Said pin (1 also extends within the slot (1, formed in the transfer-bar d. Said transfer-bar d is normally held in the position shown in Fig. but whenever the adding-wheel of the next lower denomination is moved ten teeth said transfer-bar is caused to drop, partly by its own weight and partly by the tension of the spring (1, connected to the rod (1 which rod extends across the frame of the machine, and thereby the pin in the slot (1 is forced downwardly, which in turn draws the pivoted arm d downwardly, and the pin (1 thereupon moves from the lower portion of the slot in the arm d along the inclined surfaced which movement on the inclined surface forces'the plate I), Fig. 33, rearwardly and advances the actuating-bar and its tooth until the pin 5 contacts against the other end of the slot 6 formed in said actuatingarm. Thereby the adding-wheel is advanced a distance equal to one tooth of said wheel and is held in advanced position by a spring,- pressed crank-arm 03 through the agencyof the roller (i on the arm d resting upon the curved surface of the projecting part 03 Said roller (i is normally held in proper position to rest upon said curved surface by a spring (1. A crank-arm d is operated by projections or teeth (1, Fig. 34, projectin from the disk of the adding-wheel, there being five of. said projections or teeth, as hereinbefore explained. When the upper end of said crank-arrrfd is moved by a tooth I on the disk of the next lower adding-wheel contacting against the beveled end (1 of said crank-arm d, the. lower arm d of said crankarm (1, forming a latch for the lower arm of the crank-arm (Z is withdrawn from engagement therewith, and the spring 02 operates position.

said crank-arm (2, thereby causing the roller on the arm d to drop away from the curved surface df", which causes the transfer-bar (Z to drop for the urpose of causing the trans fer from one w eel to the next higher wheel, as just previously explained. The transferbars (1 are returned to normal position by the rod d which is supported by the bifurcated spring-pressed arms (1", having the pin d, adapted to be engaged by the pivoted operating-pawl 17*, formed on the hub 1), Figs. 2 and 35, and, as shown in Fig. 3, the pivoted operating-pawl 11 drops into' engagement with the pin cl at the end of the rearward movement of the operating-wheel, and the pawl b by contact against the pin d 'at the beginning of the return movement of the main operating-wheel raises the rod 11 up wardly, said rod extending across the machine and partly below the transfer-bars d, thereby raising all transfer-bars which have dropped to normal position, when the roller (i will be engaged by the crank-arm d, which crank-arm will have been prior thereto returned to proper position by said rod d contacting against the upper part of the crankarm (1 and forcing same back to normal position.

The surface (1 is curved, as shown in Fig. 35, and is formed ,concentric with the center of the shaft 9. The arrangement is one which results in a quick and positive dropping of the transfer-bar for the purpose of insuring an accurate transfer from one wheel to the next succeeding wheel.

We have shown transfer mechanism in two different views. In Fig. 35 the parts are in normal position before any transfer is made. In Fig. 52 we have shown the transfer mechanism just after the transfer has been made and before the parts are returned to normal It will be perceived that in Fig. 35 the transfer-bar d is shown in its upper or normal position and held there by the springpressed crank-arm d so that the roller (i engages'the curved surface of the projecting part d, whereas in Fig. 52 the transfer-bar 'd is shown in its lower position with the roller d out of engagement with the curved surface of the projecting part ri and dropped below said surface. In Fig. 35 we have shown the crank-arm d in such position that the lower arm d has a shoulder formed thereon in engagement with'the pin on the lower end of the crank-arm d and ready to operate said crank-arm whenever the upper end of the crank-arm d" is moved by the con tact of the tooth on the disk of the addingwheel with the pin d. This will occur whenever the adding-wheel makes one-fifth of a revolution. In Fig. 52 we have shown the lower arm (1 of the crank-arm d with the shoulder out of engagement with the pin formed on the crank-arm (Z and the arm d has moved the crank-arm (1 so as to throw 

